The influence of heat treatment on microstructure and mechanical response of a newly developed non-equimolar AlCrCuFeNi high-entropy alloy: Experiments and numerical modeling

The influence of heat treatment on microstructure and mechanical response of a newly developed non-equimolar AlCrCuFeNi high-entropy alloy: Experiments and numerical modeling

High Entropy Alloys (HEA), or more generally, Complex Concentrated Alloys (CCA) have recently shifted the manufacturing and design paradigms of metallic alloys which are more resistant and strong to mechanical loadings as well as environmental-assisted cracking. Although an extensive body of results...

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Bibliographic Details
Published in:Materials characterization Vol. 207; p. 113544
Main Authors: Xue, Lufeng, Cai, Wang, Sun, Yeting, Paredes, Marcelo, Sun, Chaoyang, Bai, Yuanli
Format: Journal Article
Language:English
Published: Elsevier Inc 01-01-2024
Subjects:
Crystal plasticity HEA
HEA alloys
Microstructure characterization
Phenomenological model HEA
Microstructure characterization
Crystal plasticity HEA
HEA alloys
Phenomenological model HEA
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Summary:High Entropy Alloys (HEA), or more generally, Complex Concentrated Alloys (CCA) have recently shifted the manufacturing and design paradigms of metallic alloys which are more resistant and strong to mechanical loadings as well as environmental-assisted cracking. Although an extensive body of results on these special alloying systems has accrued over recent years, there are still many unknowns related to composition and microstructure and their influences on plastic deformation and failure. In this exploratory study, a new non-equimolar Multi-Principal Element Alloy along with a few annealed variant configurations is investigated by means of microstructure characterization techniques along with computational modeling. The latter is implemented to unveil the interaction of distinct mechanisms controlling the deformation process and failure in this system. For macroscopic behavior, a phenomenological approach is used to understand the plasticity and fracture under different stress states, while a mesoscale-level crystal plasticity model is carried out to determine slip system activity and its influence on plastic deformation. Overall, the new alloy exhibits rising strain hardening curves regardless of the annealing time period, but the onset of fracture is highly sensitive to heat treatment time. •The current work characterizes thoroughly the microstructure of a newly developed multiple principal element alloy (MPEA) via EBSD, SEM, and EDS.•Important features emanating from this system alloy and corresponding variances due to different heat treatments and annealing processes are well-captured.•Computational techniques are employed to elucidate plastic deformation mechanisms at two different length scales: meso and macro levels continuum models.•The crystal plasticity method along with a phenomenological damage indicator model are carried out to highlight different acting mechanisms responsible for failure and plastic deformation.
ISSN:1044-5803
1873-4189
DOI:10.1016/j.matchar.2023.113544